Non-Peptide Gonadotropin-Releasing Hormone Receptor Antagonists

Apr 18, 2008 - R. Scott Struthers received his Ph.D. in Physiology and Pharmacology from the University of California, San Diego, under the supervisio...
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 Copyright 2008 by the American Chemical Society

Volume 51, Number 12

June 26, 2008

PerspectiVe Non-Peptide Gonadotropin-Releasing Hormone Receptor Antagonists Stephen F. Betz, Yun-Fei Zhu, Chen Chen, and R. Scott Struthers* Endocrinology & Metabolism, Neurocrine Biosciences, Inc., 12790 El Camino Real, San Diego, California 92130 ReceiVed October 3, 2007

Introduction Gonadotropin-releasing hormone (GnRHa) is the principal neuroendocrine regulator of the reproductive system in humans. It is a linear decapeptide, pGlu-His-Trp-Ser-Tyr-Gly-Leu-ArgPro-Gly-NH2, that was first isolated from porcine and ovine hypothalamii.1,2 This peptide and related isoforms have subsequently been identified in a wide range of species, indicating that core features of the sequence have been conserved over ∼600 million years of chordate evolution.3–6 The GnRH peptide is made by neurons in the hypothalamus and secreted in pulses approximately hourly into the portal blood supplying the pituitary (Figure 1).7 There, it stimulates secretion of the gonadotropins, luteinizing hormone (LH) and follicle-stimulating hormone (FSH), into the general circulation. The gonadotropins in turn act at the gonads to support spermatogenesis and synthesis of testosterone in the male and follicular development and production of estrogen and progesterone in the female. Gonadal steroids in turn feed back to regulate the hypothalamus and pituitary. The actions of GnRH are mediated by the GnRH receptor (GnRH-R).4 It is a member of the rhodopsin family of seventransmembrane receptors and was first cloned from the mouse8 and subsequently from a variety of other species, including human.3,9–11 It differs from other class A GPCRs by the absence of a C-terminal tail, which is a predominate site of regulation * To whom correspondence should be addressed. Phone: 858-617-7740. Fax: 858-617-7696. E-mail: [email protected]. a Abbreviations: AUC, area under the curve; b.i.d., twice daily dosing; Cmax, highest concentration; E2, estradiol; ECL, extracellular loop; FSH, follicle-stimulating hormone; GnRH, gonadotropin-releasing hormone; GnRH-R, gonadotropin-releasing hormone receptor; GPCR, G-proteincoupled receptor; GTPase, guanosine triphosphatase; HPG, hypothalamicpituitary–gonadal; im, intramuscular; ip, intraperitoneal; IVF, in vitro fertilization; LH, luteinizing hormone; NTD, N-terminal domain; sc, subcutaneous; TM, transmembrane.

by various kinases in other family members.12 Binding of GnRH induces a conformational change in the receptor, which in turn activates the GTPases GRq and GR11 resulting in G-protein activation, which stimulates activity of phospholipase C resulting in phosphatidyl inositol turnover,13 intracellular calcium release, and gonadotropin secretion.14 Continuous agonist administration causes an initial stimulatory effect, followed by desensitization of the pituitary and eventually down-regulation of gonadotropin secretion over the course of 1-2 weeks.15–16 This pituitary down-regulation leads to a profound suppression of the reproductive endocrine axis and can be exploited therapeutically to produce medical gonadectomy which reduces circulating sex steroids to levels equivalent to surgical castration.17 On the basis of this somewhat paradoxical mechanism, several GnRH agonist peptides such as leuprolide, goserelin, and triptorelin are now commercially available in long acting injectable depot formulations for gonadal suppression. They have found widespread utility for a range of steroid hormone dependent diseases17 and assisted reproductive therapy18 as outlined in Table 1. Early studies in the structure–activity relationships of GnRH peptides identified His2 as critical for receptor activation.22 Substitutions with D-amino acids at this position and optimization of multiple additional residues in the peptide led to the identification of potent antagonists.23 These efforts eventually led to multiple peptides that have been evaluated in clinical studies.20,24 In contrast to the initial stimulation caused by agonists, antagonists immediately inhibit pituitary gonadotropin secretion.25 Thus, in patients with advanced prostate cancer, antagonists avoid the initial “flare” in testosterone produced by agonists and result in a more rapid reduction in testosterone.26,27 Analogously in women, peptide antagonists reduce uterine fibroid volume in 2-4 weeks, more rapidly than is observed with agonist therapy.28,29 Antagonists also require fewer injec-

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Table 1. Peptide GnRH-R Modulators Approved for Use in the U.S.

a Based on label information available at the U.S. Food and Drug Administration Web site (www.fda.gov). reviews of the clinical uses of peptide GnRH-R agonists and antagonists, see refs 17, 19–21.

Figure 1. Schematic overview of the hypothalamic-pituitary–gonadal axis.

tions and reduction in the duration of treatment during in vitro fertilization protocols.20 Several peptide GnRH-R antagonists, including cetrorelix, ganirelix, and abarelix, have subsequently become commercially available for clinical use (although marketing of abarelix has recently been discontinued). Cetrorelix and ganirelix are currently available only in formulations for short acting subcutaneous injection. Abarelix, which was available as a long acting depot for prostate cancer, requires careful patient monitoring because of occurrences of immediateonset systemic allergic reactions. Depot preparations of the next generation peptide antagonists degarelix30,31 and ozarelix32 are currently in late stage clinical development. With the exception of nafarelin, which is formulated as a nasal spray, peptide

b

Marketing discontinued in 2007. c For

GnRH-R modulators require parenteral administration. Injection site reactions can sometimes occur. Furthermore, treatment cannot be readily discontinued or modified with the depot preparations. Since the earliest days of GnRH peptide analogues, there has been significant interest in developing orally active agents. As early as 1982, oral activity of a peptide antagonist to suppress ovulation in female rats was demonstrated, albeit with poor apparent oral bioavailability (99.9%, providing a potential explanation for the high concentrations required to achieve maximum testosterone suppression in vivo. Thus, both orthosteric and allosteric antagonists can achieve maximum testosterone suppression in the rat given sufficient exposure of the antagonist at the pituitary. Because of the weak activity of 2 and 13 at rat GnRH-R, cynamolgus macaques were used preclinically to characterize the in vivo activity of these compounds. Compound 2 has a very high binding affinity for the macaque GnRH-R (IC50 ) 0.6 nM) when expressed in CHO cells and is also potent in functional inhibition of arachadonic acid release (IC50 ) 10 nM)

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Figure 22. Comparison of different binding motifs to human GnRH-R. Left: 57 binds primarily to TM6 and TM7, an area of low GPCR specificity. Compound 2 possesses interactions with multiple TMs 3, 5, 6, and 7 as well as interactions with the “trap door” residues L300(6.68) and M24 (each shown in green). Right: Similarly, 55 binds primarily to TM6 and TM7, while 13 has interactions with multiple TMs 3, 5, and 6 as well as interactions with the “trap door” residues. M24 position is shown for hypothesis purposes only.

in these cells.44 Potency for inhibition of LH release from cultured macaque pituitary cells was 36 nM.114 In castrate male macaques, 2 (10 mg/kg, po) suppresses LH to 18% of predose baseline by 8 h after administration.44 Higher doses (30 mg/ kg) suppresses LH to 11% of baseline versus vehicle. Exposure in cynomolgus macaques following oral administration of 10 mg/kg is high compared to its receptor affinity (Cmax ) 0.21 µM, AUC0–6 ) 0.85 µM · h),44 suggesting that the receptor should be fully occupied. However, while chronic treatment of macaques with very high doses of 2 (30 mg/kg three times per day for 80 days) showed strong suppression of circulating LH, it did not suppress FSH.114 This regimen abolished menstrual cyclicity during treatment, and the monkeys returned to normal cyclicity and steroid profiles after discontinuation. Estrogen levels, however, although reduced, did not remain at castrate levels as has been reported in similar experiments for monkeys treated chronically with peptide agonists.115 Whether this lack of complete gonadal suppression in the macaque is due to lack of FSH suppression and/or residual levels of LH is unclear. In comparison, the orthosteric surmountable antagonist 13 suppresses LH in castrate macaques to 32% of pretreatment doses. Antagonist plasma concentrations of 10-50 ng/mL were required to maintain a maximal level of pituitary suppression. Data for intact male monkeys (rhesus macaque) are only available for the quinolone, 43.68 While its binding affinities for human and rhesus GnRH-Rs are similar (0.4 and 0.5 nM, respectively), it is somewhat less potent at the monkey receptor in an inositol phosphate functional assay (IC50 ) 1.0 and 7.0 nM, respectively). Following iv dosing of this compound, LH pulsatility was prevented and overall LH exposure reduced an average of 79% (based on LH AUC). Testosterone was reduced to near castrate levels, but residual LH and testosterone levels suggest that the HPG axis was not completely suppressed. Overall, as with peptide antagonists, castrate levels of testosterone can be achieved (at least in the rat) with sufficient exposure. While the data are not complete, the overall picture for three different classes of first generation non-peptide antagonists in monkeys suggests that these compounds may not suppress the HPG axis as completely as has previously been demonstrated for peptide agonists. However, differences in

animals, experimental conditions, and hormone assay methods make these types of historical comparisons problematic. One area where non-peptides may diverge from the peptide antagonists is the lack of injection site reactions and systemic allergic reactions that hindered development of early peptide GnRH antagonists.116 These side effects are thought to associated with the direct stimulation of histamine release by mast cells and do not appear to be mediated by GnRH-R.117,118 This was mitigated in third-generation peptide antagonists such as cetrorelix and ganirelix, which have been widely used in patients undergoing IVF treatment. However, abarelix (which was approved for use in prostate cancer but subsequently withdrawn from the market) showed cases of immediate-onset systemic allergic reactions, some resulting in hypotension and syncope. While this may be a direct effect of the peptide, it has also been suggested that carboxymethylcellulose in the depot formulation of abarelix may be the cause of this hypersensitivity.119 Because of these considerations, direct stimulation of histamine release was thought to be an unlikely action of the non-peptide antagonists, and this was subsequently confirmed for two different chemical classes.65,120 Clinical Development The development of non-peptide GnRH-R antagonists is still in its early stages, and as yet no compound has achieved regulatory approval for clinical use. Several compounds have entered clinical development, but detailed reports of results are sparse. Given the early leadership of the Takeda group, it was not surprising that their compound 2 was the first non-peptide GnRH-R antagonist to be evaluated in humans. Results of several studies have been described at scientific meetings121–125 and provide the first demonstrations of oral non-peptide GnRH-R antagonist activity in humans. In normal healthy male volunteers,123 this compound showed suppression of serum testosterone at doses as low as 10 mg, despite relatively low exposure (Cmax ) 15 ( 3 ng/mL; AUC(0,8) ) 173 ( 31 (ng · h)/ mL; mean ( SD). Doses up to 200 mg (Cmax ) 274 ( 178 ng/mL; AUC(0,8) ) 2563 ( 1595 (ng · h)/mL) were well tolerated, and increasing dose showed increasing gonadal suppression. A combined single and multiple dose study in

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Figure 23. Suppression of serum LH in postmenopausal women following oral administration of 13. Subjects were administered 5 mg (2, N ) 6), 25 mg (0, N ) 6), 100 mg (3, N ) 6), or 200 mg (b, N ) 6) of 13 or vehicle (O, N ) 8) at t ) 0. Values shown are mean ((SEM) percentage changes from the average gonadotropin concentrations for each individual baseline during the 24 h prior to administration of antagonist. A predose mean baseline LH curve for all subjects (N ) 56) is shown (9). An arrow indicates the time (t ) 0) at which antagonist was administered. Reproduced with permission from Struthers, R. S.; et al. J. Clin. Endocrinol. Metab. 2006, 91, 3903–3907.126 Copyright 2006 The Endocrine Society.

postmenopausal women121 showed rapid suppression of LH and FSH following 2 administration that persisted for at least 36 h after the last dose. Following administration of 100 mg b.i.d. for 14 days, nadir levels of circulating LH became essentially undetectable (compared to 16 IU/L in placebo treated subjects) and FSH was reduced substantially as well (3 IU/L vs 55 IU/L in placebo). However, this was associated with a significant reduction of exposure and t1/2 and a dose-dependent increase in the ratio of urinary 6-hydroxycortisol to cortisol consistent with induction of CYP3A4. In a 14-day study of 2 with 5–100 mg administration to healthy premenopausal women, LH and E2 were suppressed at all dose levels, though no significant effect on FSH was observed.122 At the highest dose (100 mg) estradiol was suppressed to very low levels (median E2 concentration of 6 pmol/L), although low levels, with greater variability, were seen even at the lowest dose (5 mg). Exposure and t1/2 were reduced on day 14, and a dose dependent increase in the urinary 6-hydroxycortisol/cortisol ratio was observed, consistent with the observations in postmenopausal women. Although the compound was evaluated in a phase II study in patients with endometriosis, it did not meet criteria for advancement into phase III studies according to information on Takeda’s Web site. Recently, a study of the uracil compound 13 on pituitary suppression in 56 postmenopausal women was published.126 Doses between 5 and 200 mg were evaluated. The compound was rapidly absorbed following oral administration (tmax ) 0.4–1.1 h) and a dose dependent suppression of LH was observed (Figure 23). Because of the relatively short pharmacokinetic half-life (2.7 ( 0.3 to 4.8 ( 0.8 h), the duration of LH suppression is dependent upon the dose, but maximum suppression is maintained for 12 h or more with 200 mg. Analysis of the pharmacokinetic and pharmacodynamic data suggested that concentrations above 20 ng/mL are required to maintain maximum LH suppression. Thus, the range of pituitary suppression that can be achieved illustrates a key difference between oral GnRH antagonists and the down-regulating peptide agonists that essentially act as an on/off switch. In addition,

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compared to various peptide antagonist depots, the degree and duration of LH suppression during the day can be varied. Suppression of FSH was less pronounced, as has been seen in some previous studies with peptide GnRH-R antagonists.25,127,128 This compound did not advance into phase II studies, but a second compound from Neurocrine, NBI-56418 (also known as elagolix), was advanced to clinical development129 and has recently completed two 3-month phase IIa studies in patients with endometriosis.130 This compound is currently being evaluated in additional phase IIb trials. One of the most difficult problems in drug discovery is the prediction of clinical pharmacokinetics and pharmacodynamics from preclinical information. As discussed above, speciesdependent differences in receptor activity of many non-peptide GnRH-R antagonists make this challenge even more difficult. With the data available on 2 and 13 some interesting observations can be made. For example, 2 suppresses LH and estrogen, but not FSH, in female cynomolgus macaques and premenopausal women. Although menstrual cyclicity in macaques is abolished, estradiol levels are not maximally suppressed in contrast to premenopausal women, who achieve profoundly suppressed levels. Although the compound has ∼6- to 170-fold lower affinity for the monkey receptor than the human receptor,44 depending on the assay, high exposure in the macaques due to three times a day dosing should have resulted in nearly complete receptor occupancy. However, we have also recently shown that in addition to differences in affinity of 2 for human and macaque GnRH-Rs, the resulting functional pharmacology is also different. At the human receptor, 2 is an insurmountable antagonist as measured by inositol phosphate production, while under similar conditions it is a fully surmountable antagonist at the macaque receptor.107 Thus, in the physiologic context of pulsatile GnRH secretion, the insurmountable antagonism at the human receptor may result in more complete prevention of receptor signaling than the surmountable antagonism at the monkey pituitary. On the other hand, 13 is a surmountable antagonist of both human and macaque receptors.120 Yet despite similar receptor pharmacology between the species, relative potency and efficacy remain difficult to predict a priori. In castrate macaques, concentrations of the antagonist of ∼10-50 ng/mL (20-100 nM) were required to maintain maximum pituitary suppression. Surprisingly, this is comparable to the plasma concentrations required to suppress LH in postmenopausal women126 even though its potency as assessed by in vitro assays is reduced 10to 17-fold between the two species. Thus, comparison of the preclinical and clinical results for 2 and 13 illustrates the inherent difficulties in quantitatively predicting pharmacologic effects in humans from in vitro and nonhuman in vivo data. Conclusions and Future Directions The diverse and critical roles of biologically active peptides acting at GPCRs together with the example of the archetypical non-peptide opiates have inspired efforts by many groups toward the discovery of non-peptide drugs. Initial peptidomimetics emerged from the field of peptide chemistry and were based on defining the bioactive peptide conformation, with attempts to replicate that pharmacophore on a non-peptide scaffold.131–133 While often elegant, successes were relatively scarce. Subsequently, improvements in screening technologies were employed to identify lead structures that were then optimized using medicinal chemistry. Non-peptide ligands for many different peptide receptors have now been identified using this approach,134,135 and approved drugs against several of these have emerged.

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These include angiotensin antagonists (losartan, candesartan, valsartan, irbesartan, olmesartan, telmisartan, eprosartan), CCR5 antagonists (maraviroc), neurokinin antagonists (aprepitant), endothelin antagonists (bosentan), and vasopressin antagonists (conivaptan). What is remarkable about the field of non-peptide GnRH-R antagonists is that although the native peptide ligand is relatively small, a wide variety of chemical classes can be recognized by the receptor binding pocket with high affinity. Although some residues in the receptor interact with both peptide and nonpeptide ligands, there is no clear correspondence between functional groups to indicate a peptidomimetic relationship. Moreover, different classes of non-peptide ligands bind to different subregions of the receptor active site. In some cases these are partially overlapping and in other cases these are nonoverlapping, resulting in non-peptide pairs that bind with allosteric pharmacology. Despite the broad chemical diversity available for high affinity ligands to human GnRH-R, very few have led to drug candidates thus far. In part, we speculate that this may be due to the inherent “drugability” of the specific subsite of the receptor recognized by each chemical class. For example, ligands that bind deeply in the transmembrane region of the receptor utilize interactions with residues that are broadly conserved across class A GPCRs, and thus lead optimization efforts are continuously forced to swim upstream against selectivity issues while trying to solve all the other typical pharmaceutical optimization challenges. In contrast, successful subsites, such as that recognized by uracils and thienopyrimidinediones, utilize nonconserved regions in the extracellular domains and can result in very high affinity binding, which may not be possible at other subsites. Thus, studies with GnRH-R begin to provide a structural explanation for what has long been recognized by medicinal chemists working on GPCRs: some chemical series are simply intractable dead ends, while others lead to rich veins of good drug candidates. Orally available, non-peptide GnRH-R antagonists may offer more than simply a more convenient and acceptable route of administration compared to GnRH peptide drugs. The ability to easily modify dosage to vary the degree and duration of pituitary suppression is a fundamental change in paradigm from the peptide depots. How this will be utilized in the human population remains to be determined through clinical studies, some of which are already underway. In the area of women’s health, this may enable suppression of the menstrual cycle and maintence of low, but not menopausal, estrogen levels in order to treat benign gynecological conditions such as endometriosis or uterine fibroids, without incurring hypoestrogenic side effects such as hot flashes and bone loss. Analogous approaches may be suitable for benign prostate hyperplasia. With the wide range of indications that can be treated by reduction in gonadal steroids, many potential opportunities exist for non-peptide GnRH-R antagonists to make a significant impact on the practice of medicine. Results from clinical trials in the coming years will tell us how well various individual compounds live up to this potential. Acknowledgment. The authors thank our many colleagues at Neurocrine Biosciences for a long history of thoughtprovoking discussions that have led to our collective view of the field that we have attempted to capture in this manuscript. Biographies Stephen F. Betz earned his Ph.D. in Chemistry from the University of North Carolina at Chapel Hill where he studied protein structure and stability. He pursued postdoctoral studies in the

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laboratory of William DeGrado at the DuPont Merck Pharmaceutical Company where he focused on protein engineering and de novo design. He moved to pharmaceutical discovery in the Research NMR Group at Abbott Laboratories, working on protein structure, structure-guided drug design, assay development, and compound screening in several different therapeutic areas. Subsequently, he led laboratory efforts at GeneFormatics, a biotechnology company founded on protein function annotation and characterization. Currently, he is Director of Endocrinology and Metabolism at Neurocrine Biosciences, and works on the discovery and development of GnRH-R antagonists and non-peptide modulators of other targets. Yun-Fei Zhu received his Ph.D. in Organic Chemistry from Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences in China, and pursued his postdoctoral studies in the laboratory of Professor Murray Goodman in Department of Chemistry, University of California, San Diego. He joined Neurocrine Biosciences in 1997 and is currently Director of Chemistry in the Endocrinology and Metabolism group. His research has involved discovery of small molecule IGF-BP inhibitors and CRFR2 and MCH receptor antagonists, and he is currently focused on the discovery and development of novel non-peptide GnRH-R antagonists for treatment of hormone-dependent diseases. Chen Chen is currently Senior Director of Medicinal Chemistry at Neurocrine Biosciences. He received his Ph.D. degree in Organic Chemistry from the Shanghai Institute of Organic Chemistry, China, and obtained his postdoctoral training with Nobel Laureate, Sir Derek Barton at Texas A&M University. His recent research interests include developing therapeutic agents for the treatment of CNS and metabolic diseases and understanding the relationship between chemical properties and pharmacokinetics. He has published over 100 research papers in peer-reviewed journals and shares 25 patents. R. Scott Struthers received his Ph.D. in Physiology and Pharmacology from the University of California, San Diego, under the supervision of Professor Wylie Vale at the Salk Institute for Biological Studies. Following his degree, Dr. Struthers joined Biosym Technologies where he led their contract research efforts developing and applying computational tools for drug discovery. He subsequently cofounded ScienceMedia Inc. to develop science education software. In 1998, he joined Neurocrine Biosciences and initiated the company’s efforts to discover non-peptide GnRH-R antagonists. His research interests include reproductive and metabolic endocrinology, GPCR ligand recognition and signaling, and drug discovery. Dr. Struthers is currently Senior Director and Head, Endocrinology and Metabolism at Neurocrine Biosciences.

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